@@ -103,6 +103,7 @@ endif
obj-y += mstar/
obj-y += mvebu/
obj-$(CONFIG_ARCH_MXS) += mxs/
+obj-$(CONFIG_ARCH_NUVOTON) += nuvoton/
obj-$(CONFIG_COMMON_CLK_NXP) += nxp/
obj-$(CONFIG_COMMON_CLK_PISTACHIO) += pistachio/
obj-$(CONFIG_COMMON_CLK_PXA) += pxa/
new file mode 100644
@@ -0,0 +1,4 @@
+# SPDX-License-Identifier: GPL-2.0-only
+obj-$(CONFIG_ARCH_NUVOTON) += clk-ma35d1.o
+obj-$(CONFIG_ARCH_NUVOTON) += clk-ma35d1-divider.o
+obj-$(CONFIG_ARCH_NUVOTON) += clk-ma35d1-pll.o
new file mode 100644
@@ -0,0 +1,144 @@
+// SPDX-License-Identifier: GPL-2.0-only
+/*
+ * Copyright (C) 2023 Nuvoton Technology Corp.
+ * Author: Chi-Fang Li <cfli0@nuvoton.com>
+ */
+
+#include <linux/clk-provider.h>
+#include <linux/slab.h>
+#include <linux/io.h>
+#include <linux/err.h>
+#include <linux/spinlock.h>
+
+#include "clk-ma35d1.h"
+
+#define div_mask(width) ((1 << (width)) - 1)
+
+struct ma35d1_adc_clk_divider {
+ struct clk_hw hw;
+ void __iomem *reg;
+ u8 shift;
+ u8 width;
+ u32 mask;
+ const struct clk_div_table *table;
+ spinlock_t *lock;
+};
+
+#define to_ma35d1_adc_clk_divider(_hw) \
+ container_of(_hw, struct ma35d1_adc_clk_divider, hw)
+
+static unsigned long ma35d1_clkdiv_recalc_rate(struct clk_hw *hw,
+ unsigned long parent_rate)
+{
+ unsigned int val;
+ struct ma35d1_adc_clk_divider *dclk = to_ma35d1_adc_clk_divider(hw);
+
+ val = readl_relaxed(dclk->reg) >> dclk->shift;
+ val &= div_mask(dclk->width);
+ val += 1;
+ return divider_recalc_rate(hw, parent_rate, val, dclk->table,
+ CLK_DIVIDER_ROUND_CLOSEST, dclk->width);
+}
+
+static long ma35d1_clkdiv_round_rate(struct clk_hw *hw, unsigned long rate,
+ unsigned long *prate)
+{
+ struct ma35d1_adc_clk_divider *dclk = to_ma35d1_adc_clk_divider(hw);
+
+ return divider_round_rate(hw, rate, prate, dclk->table,
+ dclk->width, CLK_DIVIDER_ROUND_CLOSEST);
+}
+
+static int ma35d1_clkdiv_set_rate(struct clk_hw *hw, unsigned long rate,
+ unsigned long parent_rate)
+{
+ int value;
+ unsigned long flags = 0;
+ u32 data;
+ struct ma35d1_adc_clk_divider *dclk = to_ma35d1_adc_clk_divider(hw);
+
+ value = divider_get_val(rate, parent_rate, dclk->table,
+ dclk->width, CLK_DIVIDER_ROUND_CLOSEST);
+
+ if (dclk->lock)
+ spin_lock_irqsave(dclk->lock, flags);
+
+ data = readl_relaxed(dclk->reg);
+ data &= ~(div_mask(dclk->width) << dclk->shift);
+ data |= (value - 1) << dclk->shift;
+ data |= dclk->mask;
+
+ writel_relaxed(data, dclk->reg);
+
+ if (dclk->lock)
+ spin_unlock_irqrestore(dclk->lock, flags);
+
+ return 0;
+}
+
+static const struct clk_ops ma35d1_adc_clkdiv_ops = {
+ .recalc_rate = ma35d1_clkdiv_recalc_rate,
+ .round_rate = ma35d1_clkdiv_round_rate,
+ .set_rate = ma35d1_clkdiv_set_rate,
+};
+
+struct clk_hw *ma35d1_reg_adc_clkdiv(struct device *dev, const char *name,
+ const char *parent_name,
+ unsigned long flags, void __iomem *reg,
+ u8 shift, u8 width, u32 mask_bit)
+{
+ struct ma35d1_adc_clk_divider *div;
+ struct clk_init_data init;
+ struct clk_div_table *table;
+ u32 max_div, min_div;
+ struct clk_hw *hw;
+ int ret;
+ int i;
+
+ /* allocate the divider */
+ div = kzalloc(sizeof(*div), GFP_KERNEL);
+ if (!div)
+ return ERR_PTR(-ENOMEM);
+
+ /* Init the divider table */
+ max_div = div_mask(width) + 1;
+ min_div = 1;
+
+ table = kcalloc(max_div + 1, sizeof(*table), GFP_KERNEL);
+ if (!table) {
+ kfree(div);
+ return ERR_PTR(-ENOMEM);
+ }
+
+ for (i = 0; i < max_div; i++) {
+ table[i].val = (min_div + i);
+ table[i].div = 2 * table[i].val;
+ }
+ table[max_div].val = 0;
+ table[max_div].div = 0;
+
+ init.name = name;
+ init.ops = &ma35d1_adc_clkdiv_ops;
+ init.flags |= flags;
+ init.parent_names = parent_name ? &parent_name : NULL;
+ init.num_parents = parent_name ? 1 : 0;
+
+ /* struct ma35d1_adc_clk_divider assignments */
+ div->reg = reg;
+ div->shift = shift;
+ div->width = width;
+ div->mask = mask_bit ? BIT(mask_bit) : 0;
+ div->lock = &ma35d1_lock;
+ div->hw.init = &init;
+ div->table = table;
+
+ /* Register the clock */
+ hw = &div->hw;
+ ret = clk_hw_register(NULL, hw);
+ if (ret) {
+ kfree(table);
+ kfree(div);
+ return ERR_PTR(ret);
+ }
+ return hw;
+}
new file mode 100644
@@ -0,0 +1,534 @@
+// SPDX-License-Identifier: GPL-2.0-only
+/*
+ * Copyright (C) 2023 Nuvoton Technology Corp.
+ * Author: Chi-Fang Li <cfli0@nuvoton.com>
+ */
+
+#include <linux/clk.h>
+#include <linux/clk-provider.h>
+#include <linux/io.h>
+#include <linux/slab.h>
+#include <linux/bitfield.h>
+
+#include "clk-ma35d1.h"
+
+#define to_ma35d1_clk_pll(clk) \
+ (container_of(clk, struct ma35d1_clk_pll, clk))
+
+#define PLL0CTL0_FBDIV_MSK GENMASK(7, 0)
+#define PLL0CTL0_INDIV_MSK GENMASK(11, 8)
+#define PLL0CTL0_OUTDIV_MSK GENMASK(13, 12)
+#define PLL0CTL0_PD_MSK BIT(16)
+#define PLL0CTL0_BP_MSK BIT(17)
+#define PLLXCTL0_FBDIV_MSK GENMASK(10, 0)
+#define PLLXCTL0_INDIV_MSK GENMASK(17, 12)
+#define PLLXCTL0_MODE_MSK GENMASK(19, 18)
+#define PLLXCTL0_SSRATE_MSK GENMASK(30, 20)
+#define PLLXCTL1_PD_MSK BIT(0)
+#define PLLXCTL1_BP_MSK BIT(1)
+#define PLLXCTL1_OUTDIV_MSK GENMASK(6, 4)
+#define PLLXCTL1_FRAC_MSK GENMASK(31, 8)
+#define PLLXCTL2_SLOPE_MSK GENMASK(23, 0)
+
+struct ma35d1_clk_pll {
+ struct clk_hw hw;
+ u8 type;
+ u8 mode;
+ unsigned long rate;
+ void __iomem *ctl0_base;
+ void __iomem *ctl1_base;
+ void __iomem *ctl2_base;
+ struct regmap *regmap;
+};
+
+struct vsipll_freq_conf_reg_tbl {
+ unsigned long freq;
+ u8 mode;
+ u32 ctl0_reg;
+ u32 ctl1_reg;
+ u32 ctl2_reg;
+};
+
+static const struct vsipll_freq_conf_reg_tbl ma35d1pll_freq[] = {
+ { 1000000000, VSIPLL_INTEGER_MODE, 0x307d, 0x10, 0 },
+ { 884736000, VSIPLL_FRACTIONAL_MODE, 0x41024, 0xdd2f1b11, 0 },
+ { 533000000, VSIPLL_SS_MODE, 0x12b8102c, 0x6aaaab20, 0x12317 },
+ { }
+};
+
+static void CLK_UnLockReg(struct ma35d1_clk_pll *pll)
+{
+ int ret;
+
+ /* Unlock PLL registers */
+ do {
+ regmap_write(pll->regmap, REG_SYS_RLKTZNS, 0x59);
+ regmap_write(pll->regmap, REG_SYS_RLKTZNS, 0x16);
+ regmap_write(pll->regmap, REG_SYS_RLKTZNS, 0x88);
+ regmap_read(pll->regmap, REG_SYS_RLKTZNS, &ret);
+ } while (ret == 0);
+}
+
+static void CLK_LockReg(struct ma35d1_clk_pll *pll)
+{
+ /* Lock PLL registers */
+ regmap_write(pll->regmap, REG_SYS_RLKTZNS, 0x0);
+}
+
+/* SMIC PLL for CAPLL */
+unsigned long CLK_GetPLLFreq_SMICPLL(struct ma35d1_clk_pll *pll,
+ unsigned long PllSrcClk)
+{
+ u32 u32M, u32N, u32P, u32OutDiv;
+ u32 val;
+ unsigned long u64PllClk;
+ u32 clk_div_table[] = { 1, 2, 4, 8};
+
+ val = __raw_readl(pll->ctl0_base);
+
+ u32N = FIELD_GET(PLL0CTL0_FBDIV_MSK, val);
+ u32M = FIELD_GET(PLL0CTL0_INDIV_MSK, val);
+ u32P = FIELD_GET(PLL0CTL0_OUTDIV_MSK, val);
+ u32OutDiv = clk_div_table[u32P];
+
+ if (val & PLL0CTL0_BP_MSK) {
+ u64PllClk = PllSrcClk;
+ } else {
+ u64PllClk = PllSrcClk * u32N;
+ do_div(u64PllClk, u32M * u32OutDiv);
+ }
+ return u64PllClk;
+}
+
+/* VSI-PLL: INTEGER_MODE */
+unsigned long CLK_CalPLLFreq_Mode0(unsigned long PllSrcClk,
+ unsigned long u64PllFreq, u32 *u32Reg)
+{
+ u32 u32TmpM, u32TmpN, u32TmpP;
+ u32 u32RngMinN, u32RngMinM, u32RngMinP;
+ u32 u32RngMaxN, u32RngMaxM, u32RngMaxP;
+ u32 u32Tmp, u32Min, u32MinN, u32MinM, u32MinP;
+ unsigned long u64PllClk;
+ unsigned long u64Con1, u64Con2, u64Con3;
+
+ u64PllClk = 0;
+ u32Min = (u32) -1;
+
+ if (!((u64PllFreq >= VSIPLL_FCLKO_MIN_FREQ) &&
+ (u64PllFreq <= VSIPLL_FCLKO_MAX_FREQ))) {
+ u32Reg[0] = ma35d1pll_freq[0].ctl0_reg;
+ u32Reg[1] = ma35d1pll_freq[0].ctl1_reg;
+ u64PllClk = ma35d1pll_freq[0].freq;
+ return u64PllClk;
+ }
+
+ u32RngMinM = 1UL;
+ u32RngMaxM = 63UL;
+ u32RngMinM = ((PllSrcClk / VSIPLL_FREFDIVM_MAX_FREQ) > 1) ?
+ (PllSrcClk / VSIPLL_FREFDIVM_MAX_FREQ) : 1;
+ u32RngMaxM = ((PllSrcClk / VSIPLL_FREFDIVM_MIN_FREQ0) < u32RngMaxM) ?
+ (PllSrcClk / VSIPLL_FREFDIVM_MIN_FREQ0) : u32RngMaxM;
+
+ for (u32TmpM = u32RngMinM; u32TmpM < (u32RngMaxM + 1); u32TmpM++) {
+ u64Con1 = PllSrcClk / u32TmpM;
+ u32RngMinN = 16UL;
+ u32RngMaxN = 2047UL;
+ u32RngMinN = ((VSIPLL_FCLK_MIN_FREQ / u64Con1) > u32RngMinN) ?
+ (VSIPLL_FCLK_MIN_FREQ / u64Con1) : u32RngMinN;
+ u32RngMaxN = ((VSIPLL_FCLK_MAX_FREQ / u64Con1) < u32RngMaxN) ?
+ (VSIPLL_FCLK_MAX_FREQ / u64Con1) : u32RngMaxN;
+
+ for (u32TmpN = u32RngMinN; u32TmpN < (u32RngMaxN + 1);
+ u32TmpN++) {
+ u64Con2 = u64Con1 * u32TmpN;
+ u32RngMinP = 1UL;
+ u32RngMaxP = 7UL;
+ u32RngMinP = ((u64Con2 / VSIPLL_FCLKO_MAX_FREQ) > 1) ?
+ (u64Con2 / VSIPLL_FCLKO_MAX_FREQ) : 1;
+ u32RngMaxP = ((u64Con2 / VSIPLL_FCLKO_MIN_FREQ) <
+ u32RngMaxP) ?
+ (u64Con2 / VSIPLL_FCLKO_MIN_FREQ) :
+ u32RngMaxP;
+ for (u32TmpP = u32RngMinP; u32TmpP < (u32RngMaxP + 1);
+ u32TmpP++) {
+ u64Con3 = u64Con2 / u32TmpP;
+ if (u64Con3 > u64PllFreq)
+ u32Tmp = u64Con3 - u64PllFreq;
+ else
+ u32Tmp = u64PllFreq - u64Con3;
+
+ if (u32Tmp < u32Min) {
+ u32Min = u32Tmp;
+ u32MinM = u32TmpM;
+ u32MinN = u32TmpN;
+ u32MinP = u32TmpP;
+
+ if (u32Min == 0UL) {
+ u32Reg[0] = (u32MinM << 12) |
+ (u32MinN);
+ u32Reg[1] = (u32MinP << 4);
+ return ((PllSrcClk * u32MinN) /
+ (u32MinP * u32MinM));
+ }
+ }
+ }
+ }
+ }
+
+ u32Reg[0] = (u32MinM << 12) | (u32MinN);
+ u32Reg[1] = (u32MinP << 4);
+ u64PllClk = (PllSrcClk * u32MinN) / (u32MinP * u32MinM);
+ return u64PllClk;
+}
+
+/* VSI-PLL: FRACTIONAL_MODE */
+unsigned long CLK_CalPLLFreq_Mode1(unsigned long PllSrcClk,
+ unsigned long u64PllFreq, u32 *u32Reg)
+{
+ unsigned long u64X, u64N, u64M, u64P, u64tmp;
+ unsigned long u64PllClk, u64FCLKO;
+ u32 u32FRAC;
+
+ if (u64PllFreq > VSIPLL_FCLKO_MAX_FREQ) {
+ u32Reg[0] = ma35d1pll_freq[1].ctl0_reg;
+ u32Reg[1] = ma35d1pll_freq[1].ctl1_reg;
+ u64PllClk = ma35d1pll_freq[1].freq;
+ return u64PllClk;
+ }
+
+ if (u64PllFreq > (VSIPLL_FCLKO_MIN_FREQ/(100-1))) {
+ u64FCLKO = u64PllFreq * ((VSIPLL_FCLKO_MIN_FREQ / u64PllFreq) +
+ ((VSIPLL_FCLKO_MIN_FREQ % u64PllFreq) ? 1 : 0));
+ } else {
+ pr_err("Failed to set rate %ld\n", u64PllFreq);
+ return 0;
+ }
+
+ u64P = (u64FCLKO >= VSIPLL_FCLK_MIN_FREQ) ? 1 :
+ ((VSIPLL_FCLK_MIN_FREQ / u64FCLKO) +
+ ((VSIPLL_FCLK_MIN_FREQ % u64FCLKO) ? 1 : 0));
+
+ if ((PllSrcClk > (VSIPLL_FREFDIVM_MAX_FREQ * (64-1))) ||
+ (PllSrcClk < VSIPLL_FREFDIVM_MIN_FREQ1))
+ return 0;
+
+ u64M = (PllSrcClk <= VSIPLL_FREFDIVM_MAX_FREQ) ? 1 :
+ ((PllSrcClk / VSIPLL_FREFDIVM_MAX_FREQ) +
+ ((PllSrcClk % VSIPLL_FREFDIVM_MAX_FREQ) ? 1 : 0));
+
+ u64tmp = (u64FCLKO * u64P * u64M * 1000) / PllSrcClk;
+ u64N = u64tmp / 1000;
+ u64X = u64tmp % 1000;
+ u32FRAC = ((u64X << 24) + 500) / 1000;
+ u64PllClk = (PllSrcClk * u64tmp) / u64P / u64M / 1000;
+
+ u32Reg[0] = (u64M << 12) | (u64N);
+ u32Reg[1] = (u64P << 4) | (u32FRAC << 8);
+ return u64PllClk;
+}
+
+/* VSI-PLL: SS_MODE */
+unsigned long CLK_CalPLLFreq_Mode2(unsigned long PllSrcClk,
+ unsigned long u64PllFreq,
+ u32 u32SR, u32 u32Fmod, u32 *u32Reg)
+{
+ unsigned long u64X, u64N, u64M, u64P, u64tmp, u64tmpP, u64tmpM;
+ unsigned long u64SSRATE, u64SLOPE, u64PllClk, u64FCLKO;
+ u32 u32FRAC, i;
+
+ if (u64PllFreq >= VSIPLL_FCLKO_MAX_FREQ) {
+ u32Reg[0] = ma35d1pll_freq[2].ctl0_reg;
+ u32Reg[1] = ma35d1pll_freq[2].ctl1_reg;
+ u32Reg[2] = ma35d1pll_freq[2].ctl2_reg;
+ u64PllClk = ma35d1pll_freq[2].freq;
+ return u64PllClk;
+ }
+
+ if (u64PllFreq < VSIPLL_FCLKO_MIN_FREQ) {
+ u64FCLKO = 0;
+ for (i = 2; i < 8; i++) {
+ u64tmp = (i * u64PllFreq);
+ if (u64tmp > VSIPLL_FCLKO_MIN_FREQ)
+ u64FCLKO = u64tmp;
+ }
+ if (u64FCLKO == 0) {
+ pr_err("Failed to set rate %ld\n", u64PllFreq);
+ return 0;
+ }
+
+ } else
+ u64FCLKO = u64PllFreq;
+
+ u64P = 0;
+ for (i = 1; i < 8; i++) {
+ u64tmpP = i * u64FCLKO;
+ if ((u64tmpP <= VSIPLL_FCLK_MAX_FREQ) &&
+ (u64tmpP >= VSIPLL_FCLK_MIN_FREQ)) {
+ u64P = i;
+ break;
+ }
+ }
+
+ if (u64P == 0)
+ return 0;
+
+ u64M = 0;
+ for (i = 1; i < 64; i++) {
+ u64tmpM = PllSrcClk / i;
+ if ((u64tmpM <= VSIPLL_FREFDIVM_MAX_FREQ) &&
+ (u64tmpM >= VSIPLL_FREFDIVM_MIN_FREQ1)) {
+ u64M = i;
+ break;
+ }
+ }
+
+ if (u64M == 0)
+ return 0;
+
+ u64tmp = (u64FCLKO * u64P * u64M * 1000) / PllSrcClk;
+ u64N = u64tmp / 1000;
+ u64X = u64tmp % 1000;
+ u32FRAC = ((u64X << 24) + 500) / 1000;
+
+ u64SSRATE = ((PllSrcClk >> 1) / (u32Fmod * 2)) - 1;
+ u64SLOPE = ((u64tmp * u32SR / u64SSRATE) << 24) / 100 / 1000;
+
+ u64PllClk = (PllSrcClk * u64tmp) / u64P / u64M / 1000;
+
+ u32Reg[0] = (u64SSRATE << VSIPLLCTL0_SSRATE_POS) | (u64M <<
+ VSIPLLCTL0_INDIV_POS) | (u64N);
+ u32Reg[1] = (u64P << VSIPLLCTL1_OUTDIV_POS) | (u32FRAC << VSIPLLCTL1_FRAC_POS);
+ u32Reg[2] = u64SLOPE;
+ return u64PllClk;
+}
+
+unsigned long CLK_SetPLLFreq(struct ma35d1_clk_pll *pll,
+ unsigned long PllSrcClk,
+ unsigned long u64PllFreq)
+{
+ u32 u32Reg[3] = { 0 }, val_ctl0, val_ctl1, val_ctl2;
+ unsigned long u64PllClk;
+
+ val_ctl0 = __raw_readl(pll->ctl0_base);
+ val_ctl1 = __raw_readl(pll->ctl1_base);
+ val_ctl2 = __raw_readl(pll->ctl2_base);
+
+ switch (pll->mode) {
+ case VSIPLL_INTEGER_MODE:
+ u64PllClk = CLK_CalPLLFreq_Mode0(PllSrcClk, u64PllFreq,
+ u32Reg);
+ val_ctl0 = u32Reg[0] |
+ (VSIPLL_INTEGER_MODE << VSIPLLCTL0_MODE_POS);
+ break;
+ case VSIPLL_FRACTIONAL_MODE:
+ u64PllClk = CLK_CalPLLFreq_Mode1(PllSrcClk, u64PllFreq,
+ u32Reg);
+ val_ctl0 = u32Reg[0] |
+ (VSIPLL_FRACTIONAL_MODE << VSIPLLCTL0_MODE_POS);
+ break;
+ case VSIPLL_SS_MODE:
+ u64PllClk = CLK_CalPLLFreq_Mode2(PllSrcClk, u64PllFreq,
+ VSIPLL_MODULATION_FREQ,
+ VSIPLL_SPREAD_RANGE, u32Reg);
+ val_ctl0 = u32Reg[0] |
+ (VSIPLL_SS_MODE << VSIPLLCTL0_MODE_POS);
+ break;
+ }
+
+ val_ctl1 = VSIPLLCTL1_PD_MSK | u32Reg[1];
+ val_ctl2 = u32Reg[2];
+
+ __raw_writel(val_ctl0, pll->ctl0_base);
+ __raw_writel(val_ctl1, pll->ctl1_base);
+ __raw_writel(val_ctl2, pll->ctl2_base);
+ return u64PllClk;
+}
+
+unsigned long CLK_GetPLLFreq_VSIPLL(struct ma35d1_clk_pll *pll,
+ unsigned long PllSrcClk)
+{
+ u32 u32M, u32N, u32P, u32X, u32SR, u32FMOD;
+ u32 val_ctl0, val_ctl1, val_ctl2;
+ unsigned long u64PllClk, u64X;
+
+ val_ctl0 = __raw_readl(pll->ctl0_base);
+ val_ctl1 = __raw_readl(pll->ctl1_base);
+ val_ctl2 = __raw_readl(pll->ctl2_base);
+
+ if (val_ctl1 & PLLXCTL1_BP_MSK) {
+ u64PllClk = PllSrcClk;
+ return u64PllClk;
+ }
+
+ if (pll->mode == VSIPLL_INTEGER_MODE) {
+ u32N = FIELD_GET(PLLXCTL0_FBDIV_MSK, val_ctl0);
+ u32M = FIELD_GET(PLLXCTL0_INDIV_MSK, val_ctl0);
+ u32P = FIELD_GET(PLLXCTL1_OUTDIV_MSK, val_ctl1);
+
+ u64PllClk = PllSrcClk * u32N;
+ do_div(u64PllClk, u32M * u32P);
+
+ } else if (pll->mode == VSIPLL_FRACTIONAL_MODE) {
+ u32N = FIELD_GET(PLLXCTL0_FBDIV_MSK, val_ctl0);
+ u32M = FIELD_GET(PLLXCTL0_INDIV_MSK, val_ctl0);
+ u32P = FIELD_GET(PLLXCTL1_OUTDIV_MSK, val_ctl1);
+ u32X = FIELD_GET(PLLXCTL1_FRAC_MSK, val_ctl1);
+ u64X = (u64) u32X;
+ u64X = (((u64X * 1000) + 500) >> 24);
+ u64PllClk = (PllSrcClk * ((u32N * 1000) + u64X)) /
+ 1000 / u32P / u32M;
+
+ } else {
+ u32N = FIELD_GET(PLLXCTL0_FBDIV_MSK, val_ctl0);
+ u32M = FIELD_GET(PLLXCTL0_INDIV_MSK, val_ctl0);
+ u32SR = FIELD_GET(PLLXCTL0_SSRATE_MSK, val_ctl0);
+ u32P = FIELD_GET(PLLXCTL1_OUTDIV_MSK, val_ctl1);
+ u32X = FIELD_GET(PLLXCTL1_FRAC_MSK, val_ctl1);
+ u32FMOD = FIELD_GET(PLLXCTL2_SLOPE_MSK, val_ctl2);
+ u64X = (u64) u32X;
+ u64X = ((u64X * 1000) >> 24);
+ u64PllClk = (PllSrcClk * ((u32N * 1000) + u64X)) /
+ 1000 / u32P / u32M;
+ }
+ return u64PllClk;
+}
+
+static int ma35d1_clk_pll_set_rate(struct clk_hw *hw, unsigned long rate,
+ unsigned long parent_rate)
+{
+ struct ma35d1_clk_pll *pll = to_ma35d1_clk_pll(hw);
+
+ if ((parent_rate < VSIPLL_FREF_MIN_FREQ) ||
+ (parent_rate > VSIPLL_FREF_MAX_FREQ))
+ return 0;
+
+ if ((pll->type == MA35D1_CAPLL) || (pll->type == MA35D1_DDRPLL)) {
+ pr_warn("Nuvoton MA35D1 CAPLL/DDRPLL is read only.\n");
+ return -EACCES;
+ }
+ CLK_UnLockReg(pll);
+ pll->rate = CLK_SetPLLFreq(pll, parent_rate, rate);
+ CLK_LockReg(pll);
+ return 0;
+}
+
+static unsigned long ma35d1_clk_pll_recalc_rate(struct clk_hw *hw,
+ unsigned long parent_rate)
+{
+ unsigned long pllfreq;
+ struct ma35d1_clk_pll *pll = to_ma35d1_clk_pll(hw);
+
+ if ((parent_rate < VSIPLL_FREF_MIN_FREQ)
+ || (parent_rate > VSIPLL_FREF_MAX_FREQ))
+ return 0;
+
+ switch (pll->type) {
+ case MA35D1_CAPLL:
+ pllfreq = CLK_GetPLLFreq_SMICPLL(pll, parent_rate);
+ break;
+ case MA35D1_DDRPLL:
+ case MA35D1_APLL:
+ case MA35D1_EPLL:
+ case MA35D1_VPLL:
+ pllfreq = CLK_GetPLLFreq_VSIPLL(pll, parent_rate);
+ break;
+ }
+
+ return pllfreq;
+}
+
+static long ma35d1_clk_pll_round_rate(struct clk_hw *hw, unsigned long rate,
+ unsigned long *prate)
+{
+ return rate;
+}
+
+static int ma35d1_clk_pll_is_prepared(struct clk_hw *hw)
+{
+ struct ma35d1_clk_pll *pll = to_ma35d1_clk_pll(hw);
+ u32 val = __raw_readl(pll->ctl1_base);
+
+ return (val & VSIPLLCTL1_PD_MSK) ? 0 : 1;
+}
+
+static int ma35d1_clk_pll_prepare(struct clk_hw *hw)
+{
+ struct ma35d1_clk_pll *pll = to_ma35d1_clk_pll(hw);
+ u32 val;
+
+ if ((pll->type == MA35D1_CAPLL) || (pll->type == MA35D1_DDRPLL)) {
+ pr_warn("Nuvoton MA35D1 CAPLL/DDRPLL is read only.\n");
+ return -EACCES;
+ }
+
+ CLK_UnLockReg(pll);
+ val = __raw_readl(pll->ctl1_base);
+ val &= ~VSIPLLCTL1_PD_MSK;
+ __raw_writel(val, pll->ctl1_base);
+ CLK_LockReg(pll);
+ return 0;
+}
+
+static void ma35d1_clk_pll_unprepare(struct clk_hw *hw)
+{
+ struct ma35d1_clk_pll *pll = to_ma35d1_clk_pll(hw);
+ u32 val;
+
+ if ((pll->type == MA35D1_CAPLL) || (pll->type == MA35D1_DDRPLL)) {
+ pr_warn("Nuvoton MA35D1 CAPLL/DDRPLL is read only.\n");
+ } else {
+ val = __raw_readl(pll->ctl1_base);
+ val |= VSIPLLCTL1_PD_MSK;
+ __raw_writel(val, pll->ctl1_base);
+ }
+}
+
+static const struct clk_ops ma35d1_clk_pll_ops = {
+ .is_prepared = ma35d1_clk_pll_is_prepared,
+ .prepare = ma35d1_clk_pll_prepare,
+ .unprepare = ma35d1_clk_pll_unprepare,
+ .set_rate = ma35d1_clk_pll_set_rate,
+ .recalc_rate = ma35d1_clk_pll_recalc_rate,
+ .round_rate = ma35d1_clk_pll_round_rate,
+};
+
+struct clk_hw *ma35d1_reg_clk_pll(enum ma35d1_pll_type type,
+ u8 u8mode, const char *name,
+ const char *parent,
+ unsigned long targetFreq,
+ void __iomem *base,
+ struct regmap *regmap)
+{
+ struct ma35d1_clk_pll *pll;
+ struct clk_hw *hw;
+ struct clk_init_data init;
+ int ret;
+
+ pll = kmalloc(sizeof(*pll), GFP_KERNEL);
+ if (!pll)
+ return ERR_PTR(-ENOMEM);
+
+ pll->type = type;
+ pll->mode = u8mode;
+ pll->rate = targetFreq;
+ pll->ctl0_base = base + VSIPLL_CTL0;
+ pll->ctl1_base = base + VSIPLL_CTL1;
+ pll->ctl2_base = base + VSIPLL_CTL2;
+ pll->regmap = regmap;
+
+ init.name = name;
+ init.flags = 0;
+ init.parent_names = &parent;
+ init.num_parents = 1;
+ init.ops = &ma35d1_clk_pll_ops;
+ pll->hw.init = &init;
+ hw = &pll->hw;
+
+ ret = clk_hw_register(NULL, hw);
+ if (ret) {
+ pr_err("failed to register vsi-pll clock!!!\n");
+ kfree(pll);
+ return ERR_PTR(ret);
+ }
+ return hw;
+}
new file mode 100644
@@ -0,0 +1,970 @@
+// SPDX-License-Identifier: GPL-2.0-only
+/*
+ * Copyright (C) 2023 Nuvoton Technology Corp.
+ * Author: Chi-Fang Li <cfli0@nuvoton.com>
+ */
+
+#include <linux/clk.h>
+#include <linux/clk-provider.h>
+#include <linux/clkdev.h>
+#include <linux/io.h>
+#include <linux/module.h>
+#include <linux/of.h>
+#include <linux/of_address.h>
+#include <linux/platform_device.h>
+#include <linux/spinlock.h>
+#include <dt-bindings/clock/nuvoton,ma35d1-clk.h>
+
+#include "clk-ma35d1.h"
+
+DEFINE_SPINLOCK(ma35d1_lock);
+
+static const char *const ca35clk_sel_clks[] = {
+ "hxt", "capll", "ddrpll", "dummy"
+};
+
+static const char *const sysclk0_sel_clks[] = {
+ "epll_div2", "syspll"
+};
+
+static const char *const sysclk1_sel_clks[] = {
+ "hxt", "syspll"
+};
+
+static const char *const axiclk_sel_clks[] = {
+ "capll_div2", "capll_div4"
+};
+
+static const char *const ccap_sel_clks[] = {
+ "hxt", "vpll", "apll", "syspll"
+};
+
+static const char *const sdh_sel_clks[] = {
+ "syspll", "apll", "dummy", "dummy"
+};
+
+static const char *const dcu_sel_clks[] = {
+ "epll_div2", "syspll"
+};
+
+static const char *const gfx_sel_clks[] = {
+ "epll", "syspll"
+};
+
+static const char *const dbg_sel_clks[] = {
+ "hirc", "syspll"
+};
+
+static const char *const timer0_sel_clks[] = {
+ "hxt", "lxt", "pclk0", "dummy", "dummy", "lirc", "dummy", "hirc"
+};
+
+static const char *const timer1_sel_clks[] = {
+ "hxt", "lxt", "pclk0", "dummy", "dummy", "lirc", "dummy", "hirc"
+};
+
+static const char *const timer2_sel_clks[] = {
+ "hxt", "lxt", "pclk1", "dummy", "dummy", "lirc", "dummy", "hirc"
+};
+
+static const char *const timer3_sel_clks[] = {
+ "hxt", "lxt", "pclk1", "dummy", "dummy", "lirc", "dummy", "hirc"
+};
+
+static const char *const timer4_sel_clks[] = {
+ "hxt", "lxt", "pclk2", "dummy", "dummy", "lirc", "dummy", "hirc"
+};
+
+static const char *const timer5_sel_clks[] = {
+ "hxt", "lxt", "pclk2", "dummy", "dummy", "lirc", "dummy", "hirc"
+};
+
+static const char *const timer6_sel_clks[] = {
+ "hxt", "lxt", "pclk0", "dummy", "dummy", "lirc", "dummy", "hirc"
+};
+
+static const char *const timer7_sel_clks[] = {
+ "hxt", "lxt", "pclk0", "dummy", "dummy", "lirc", "dummy", "hirc"
+};
+
+static const char *const timer8_sel_clks[] = {
+ "hxt", "lxt", "pclk1", "dummy", "dummy", "lirc", "dummy", "hirc"
+};
+
+static const char *const timer9_sel_clks[] = {
+ "hxt", "lxt", "pclk1", "dummy", "dummy", "lirc", "dummy", "hirc"
+};
+
+static const char *const timer10_sel_clks[] = {
+ "hxt", "lxt", "pclk2", "dummy", "dummy", "lirc", "dummy", "hirc"
+};
+
+static const char *const timer11_sel_clks[] = {
+ "hxt", "lxt", "pclk2", "dummy", "dummy", "lirc", "dummy", "hirc"
+};
+
+static const char *const uart_sel_clks[] = {
+ "hxt", "sysclk1_div2", "dummy", "dummy"
+};
+
+static const char *const wdt0_sel_clks[] = {
+ "dummy", "lxt", "pclk3_div4096", "lirc"
+};
+
+static const char *const wdt1_sel_clks[] = {
+ "dummy", "lxt", "pclk3_div4096", "lirc"
+};
+
+static const char *const wdt2_sel_clks[] = {
+ "dummy", "lxt", "pclk4_div4096", "lirc"
+};
+
+static const char *const wwdt0_sel_clks[] = {
+ "dummy", "dummy", "pclk3_div4096", "lirc"
+};
+
+static const char *const wwdt1_sel_clks[] = {
+ "dummy", "dummy", "pclk3_div4096", "lirc"
+};
+
+static const char *const wwdt2_sel_clks[] = {
+ "dummy", "dummy", "pclk4_div4096", "lirc"
+};
+
+static const char *const spi0_sel_clks[] = {
+ "pclk1", "apll", "dummy", "dummy"
+};
+
+static const char *const spi1_sel_clks[] = {
+ "pclk2", "apll", "dummy", "dummy"
+};
+
+static const char *const spi2_sel_clks[] = {
+ "pclk1", "apll", "dummy", "dummy"
+};
+
+static const char *const spi3_sel_clks[] = {
+ "pclk2", "apll", "dummy", "dummy"
+};
+
+static const char *const qspi0_sel_clks[] = {
+ "pclk0", "apll", "dummy", "dummy"
+};
+
+static const char *const qspi1_sel_clks[] = {
+ "pclk0", "apll", "dummy", "dummy"
+};
+
+static const char *const i2s0_sel_clks[] = {
+ "apll", "sysclk1_div2", "dummy", "dummy"
+};
+
+static const char *const i2s1_sel_clks[] = {
+ "apll", "sysclk1_div2", "dummy", "dummy"
+};
+
+static const char *const can_sel_clks[] = {
+ "apll", "vpll"
+};
+
+static const char *const cko_sel_clks[] = {
+ "hxt", "lxt", "hirc", "lirc", "capll_div4", "syspll",
+ "ddrpll", "epll_div2", "apll", "vpll", "dummy", "dummy",
+ "dummy", "dummy", "dummy", "dummy"
+};
+
+static const char *const smc_sel_clks[] = {
+ "hxt", "pclk4"
+};
+
+static const char *const kpi_sel_clks[] = {
+ "hxt", "lxt"
+};
+
+static const struct clk_div_table ip_div_table[] = {
+ {0, 2}, {1, 4}, {2, 6}, {3, 8}, {4, 10},
+ {5, 12}, {6, 14}, {7, 16}, {0, 0},
+};
+
+static const struct clk_div_table eadc_div_table[] = {
+ {0, 2}, {1, 4}, {2, 6}, {3, 8}, {4, 10},
+ {5, 12}, {6, 14}, {7, 16}, {8, 18},
+ {9, 20}, {10, 22}, {11, 24}, {12, 26},
+ {13, 28}, {14, 30}, {15, 32}, {0, 0},
+};
+
+static struct clk_hw **hws;
+static struct clk_hw_onecell_data *ma35d1_hw_data;
+
+static int ma35d1_clocks_probe(struct platform_device *pdev)
+{
+ int ret;
+ struct device *dev = &pdev->dev;
+ struct device_node *clk_node = dev->of_node;
+ void __iomem *clk_base;
+ struct regmap *regmap;
+ u32 pllmode[5] = { 0, 0, 0, 0, 0 };
+ u32 pllfreq[5] = { 0, 0, 0, 0, 0 };
+
+ dev_info(&pdev->dev, "Nuvoton MA35D1 Clock Driver\n");
+ ma35d1_hw_data = devm_kzalloc(&pdev->dev, struct_size(ma35d1_hw_data,
+ hws, CLK_MAX_IDX), GFP_KERNEL);
+
+ if (WARN_ON(!ma35d1_hw_data))
+ return -ENOMEM;
+
+ ma35d1_hw_data->num = CLK_MAX_IDX;
+ hws = ma35d1_hw_data->hws;
+
+ clk_node = of_find_compatible_node(NULL, NULL, "nuvoton,ma35d1-clk");
+ clk_base = of_iomap(clk_node, 0);
+ of_node_put(clk_node);
+ if (!clk_base) {
+ pr_err("%s: could not map region\n", __func__);
+ return -ENOMEM;
+ }
+ regmap = syscon_regmap_lookup_by_phandle(pdev->dev.of_node,
+ "nuvoton,sys");
+ if (IS_ERR(regmap))
+ pr_warn("%s: Unable to get syscon\n", __func__);
+
+ /* clock sources */
+ hws[HXT] = ma35d1_clk_fixed("hxt", 24000000);
+ hws[HXT_GATE] = ma35d1_clk_gate("hxt_gate", "hxt",
+ clk_base + REG_CLK_PWRCTL, 0);
+ hws[LXT] = ma35d1_clk_fixed("lxt", 32768);
+ hws[LXT_GATE] = ma35d1_clk_gate("lxt_gate", "lxt",
+ clk_base + REG_CLK_PWRCTL, 1);
+ hws[HIRC] = ma35d1_clk_fixed("hirc", 12000000);
+ hws[HIRC_GATE] = ma35d1_clk_gate("hirc_gate", "hirc",
+ clk_base + REG_CLK_PWRCTL, 2);
+ hws[LIRC] = ma35d1_clk_fixed("lirc", 32000);
+ hws[LIRC_GATE] = ma35d1_clk_gate("lirc_gate", "lirc",
+ clk_base + REG_CLK_PWRCTL, 3);
+
+ /* PLL */
+ of_property_read_u32_array(clk_node, "clock-pll-mode", pllmode,
+ ARRAY_SIZE(pllmode));
+ of_property_read_u32_array(clk_node, "assigned-clock-rates", pllfreq,
+ ARRAY_SIZE(pllfreq));
+
+ /* SMIC PLL */
+ hws[CAPLL] = ma35d1_reg_clk_pll(MA35D1_CAPLL, pllmode[0], "capll",
+ "hxt", pllfreq[0],
+ clk_base + REG_CLK_PLL0CTL0, regmap);
+ hws[SYSPLL] = ma35d1_clk_fixed("syspll", 180000000);
+
+ /* VSI PLL */
+ hws[DDRPLL] = ma35d1_reg_clk_pll(MA35D1_DDRPLL, pllmode[1], "ddrpll",
+ "hxt", pllfreq[1],
+ clk_base + REG_CLK_PLL2CTL0, regmap);
+ hws[APLL] = ma35d1_reg_clk_pll(MA35D1_APLL, pllmode[2], "apll", "hxt",
+ pllfreq[2], clk_base + REG_CLK_PLL3CTL0,
+ regmap);
+ hws[EPLL] = ma35d1_reg_clk_pll(MA35D1_EPLL, pllmode[3], "epll", "hxt",
+ pllfreq[3], clk_base + REG_CLK_PLL4CTL0,
+ regmap);
+ hws[VPLL] = ma35d1_reg_clk_pll(MA35D1_VPLL, pllmode[4], "vpll", "hxt",
+ pllfreq[4], clk_base + REG_CLK_PLL5CTL0,
+ regmap);
+ hws[EPLL_DIV2] = ma35d1_clk_fixed_factor("epll_div2", "epll", 1, 2);
+ hws[EPLL_DIV4] = ma35d1_clk_fixed_factor("epll_div4", "epll", 1, 4);
+ hws[EPLL_DIV8] = ma35d1_clk_fixed_factor("epll_div8", "epll", 1, 8);
+
+ /* CA35 */
+ hws[CA35CLK_MUX] = ma35d1_clk_mux("ca35clk_mux",
+ clk_base + REG_CLK_CLKSEL0, 0,
+ 2, ca35clk_sel_clks,
+ ARRAY_SIZE(ca35clk_sel_clks));
+
+ /* AXI */
+ hws[AXICLK_DIV2] = ma35d1_clk_fixed_factor("capll_div2", "ca35clk_mux",
+ 1, 2);
+ hws[AXICLK_DIV4] = ma35d1_clk_fixed_factor("capll_div4", "ca35clk_mux",
+ 1, 4);
+ hws[AXICLK_MUX] = ma35d1_clk_mux("axiclk_mux",
+ clk_base + REG_CLK_CLKDIV0,
+ 26, 1, axiclk_sel_clks,
+ ARRAY_SIZE(axiclk_sel_clks));
+
+ /* SYSCLK0 & SYSCLK1 */
+ hws[SYSCLK0_MUX] = ma35d1_clk_mux("sysclk0_mux",
+ clk_base + REG_CLK_CLKSEL0,
+ 2, 1, sysclk0_sel_clks,
+ ARRAY_SIZE(sysclk0_sel_clks));
+ hws[SYSCLK1_MUX] = ma35d1_clk_mux("sysclk1_mux",
+ clk_base + REG_CLK_CLKSEL0,
+ 4, 1, sysclk1_sel_clks,
+ ARRAY_SIZE(sysclk1_sel_clks));
+ hws[SYSCLK1_DIV2] = ma35d1_clk_fixed_factor("sysclk1_div2",
+ "sysclk1_mux", 1, 2);
+
+ /* HCLK0~3 & PCLK0~4 */
+ hws[HCLK0] = ma35d1_clk_fixed_factor("hclk0", "sysclk1_mux", 1, 1);
+ hws[HCLK1] = ma35d1_clk_fixed_factor("hclk1", "sysclk1_mux", 1, 1);
+ hws[HCLK2] = ma35d1_clk_fixed_factor("hclk2", "sysclk1_mux", 1, 1);
+ hws[PCLK0] = ma35d1_clk_fixed_factor("pclk0", "sysclk1_mux", 1, 1);
+ hws[PCLK1] = ma35d1_clk_fixed_factor("pclk1", "sysclk1_mux", 1, 1);
+ hws[PCLK2] = ma35d1_clk_fixed_factor("pclk2", "sysclk1_mux", 1, 1);
+
+ hws[HCLK3] = ma35d1_clk_fixed_factor("hclk3", "sysclk1_mux", 1, 2);
+ hws[PCLK3] = ma35d1_clk_fixed_factor("pclk3", "sysclk1_mux", 1, 2);
+ hws[PCLK4] = ma35d1_clk_fixed_factor("pclk4", "sysclk1_mux", 1, 2);
+
+ hws[USBPHY0] = ma35d1_clk_fixed("usbphy0", 480000000);
+ hws[USBPHY1] = ma35d1_clk_fixed("usbphy1", 480000000);
+
+ /* DDR */
+ hws[DDR0_GATE] = ma35d1_clk_gate("ddr0_gate", "ddrpll",
+ clk_base + REG_CLK_SYSCLK0, 4);
+ hws[DDR6_GATE] = ma35d1_clk_gate("ddr6_gate", "ddrpll",
+ clk_base + REG_CLK_SYSCLK0, 5);
+
+ /* CAN0 */
+ hws[CAN0_MUX] = ma35d1_clk_mux("can0_mux", clk_base + REG_CLK_CLKSEL4,
+ 16, 1, can_sel_clks,
+ ARRAY_SIZE(can_sel_clks));
+ hws[CAN0_DIV] = ma35d1_clk_divider_table("can0_div", "can0_mux",
+ clk_base + REG_CLK_CLKDIV0,
+ 0, 3, ip_div_table);
+ hws[CAN0_GATE] = ma35d1_clk_gate("can0_gate", "can0_div",
+ clk_base + REG_CLK_SYSCLK0, 8);
+
+ /* CAN1 */
+ hws[CAN1_MUX] = ma35d1_clk_mux("can1_mux", clk_base + REG_CLK_CLKSEL4,
+ 17, 1, can_sel_clks,
+ ARRAY_SIZE(can_sel_clks));
+ hws[CAN1_DIV] = ma35d1_clk_divider_table("can1_div", "can1_mux",
+ clk_base + REG_CLK_CLKDIV0,
+ 4, 3, ip_div_table);
+ hws[CAN1_GATE] = ma35d1_clk_gate("can1_gate", "can1_div",
+ clk_base + REG_CLK_SYSCLK0, 9);
+
+ /* CAN2 */
+ hws[CAN2_MUX] = ma35d1_clk_mux("can2_mux", clk_base + REG_CLK_CLKSEL4,
+ 18, 1, can_sel_clks,
+ ARRAY_SIZE(can_sel_clks));
+ hws[CAN2_DIV] = ma35d1_clk_divider_table("can2_div", "can2_mux",
+ clk_base + REG_CLK_CLKDIV0,
+ 8, 3, ip_div_table);
+ hws[CAN2_GATE] = ma35d1_clk_gate("can2_gate", "can2_div",
+ clk_base + REG_CLK_SYSCLK0, 10);
+
+ /* CAN3 */
+ hws[CAN3_MUX] = ma35d1_clk_mux("can3_mux", clk_base + REG_CLK_CLKSEL4,
+ 19, 1, can_sel_clks,
+ ARRAY_SIZE(can_sel_clks));
+ hws[CAN3_DIV] = ma35d1_clk_divider_table("can3_div", "can3_mux",
+ clk_base + REG_CLK_CLKDIV0,
+ 12, 3, ip_div_table);
+ hws[CAN3_GATE] = ma35d1_clk_gate("can3_gate", "can3_div",
+ clk_base + REG_CLK_SYSCLK0, 11);
+
+ /* SDH0 */
+ hws[SDH0_MUX] = ma35d1_clk_mux("sdh0_mux", clk_base + REG_CLK_CLKSEL0,
+ 16, 2, sdh_sel_clks,
+ ARRAY_SIZE(sdh_sel_clks));
+ hws[SDH0_GATE] = ma35d1_clk_gate("sdh0_gate", "sdh0_mux",
+ clk_base + REG_CLK_SYSCLK0, 16);
+
+ /* SDH1 */
+ hws[SDH1_MUX] = ma35d1_clk_mux("sdh1_mux", clk_base + REG_CLK_CLKSEL0,
+ 18, 2, sdh_sel_clks,
+ ARRAY_SIZE(sdh_sel_clks));
+ hws[SDH1_GATE] = ma35d1_clk_gate("sdh1_gate", "sdh1_mux",
+ clk_base + REG_CLK_SYSCLK0, 17);
+
+ /* NAND */
+ hws[NAND_GATE] = ma35d1_clk_gate("nand_gate", "hclk1",
+ clk_base + REG_CLK_SYSCLK0, 18);
+
+ /* USB */
+ hws[USBD_GATE] = ma35d1_clk_gate("usbd_gate", "usbphy0",
+ clk_base + REG_CLK_SYSCLK0, 19);
+ hws[USBH_GATE] = ma35d1_clk_gate("usbh_gate", "usbphy0",
+ clk_base + REG_CLK_SYSCLK0, 20);
+ hws[HUSBH0_GATE] = ma35d1_clk_gate("husbh0_gate", "usbphy0",
+ clk_base + REG_CLK_SYSCLK0, 21);
+ hws[HUSBH1_GATE] = ma35d1_clk_gate("husbh1_gate", "usbphy0",
+ clk_base + REG_CLK_SYSCLK0, 22);
+
+ /* GFX */
+ hws[GFX_MUX] = ma35d1_clk_mux("gfx_mux", clk_base + REG_CLK_CLKSEL0,
+ 26, 1, gfx_sel_clks,
+ ARRAY_SIZE(gfx_sel_clks));
+ hws[GFX_GATE] = ma35d1_clk_gate("gfx_gate", "gfx_mux",
+ clk_base + REG_CLK_SYSCLK0, 24);
+
+ /* VC8K */
+ hws[VC8K_GATE] = ma35d1_clk_gate("vc8k_gate", "sysclk0_mux",
+ clk_base + REG_CLK_SYSCLK0, 25);
+
+ /* DCU */
+ hws[DCU_MUX] = ma35d1_clk_mux("dcu_mux", clk_base + REG_CLK_CLKSEL0,
+ 24, 1, dcu_sel_clks,
+ ARRAY_SIZE(dcu_sel_clks));
+ hws[DCU_GATE] = ma35d1_clk_gate("dcu_gate", "dcu_mux",
+ clk_base + REG_CLK_SYSCLK0, 26);
+
+ /* DCUP */
+ hws[DCUP_DIV] = ma35d1_clk_divider_table("dcup_div", "vpll",
+ clk_base + REG_CLK_CLKDIV0,
+ 16, 3, ip_div_table);
+
+ /* EMAC0 */
+ hws[EMAC0_GATE] = ma35d1_clk_gate("emac0_gate", "epll_div2",
+ clk_base + REG_CLK_SYSCLK0, 27);
+
+ /* EMAC1 */
+ hws[EMAC1_GATE] = ma35d1_clk_gate("emac1_gate", "epll_div2",
+ clk_base + REG_CLK_SYSCLK0, 28);
+
+ /* CCAP0 */
+ hws[CCAP0_MUX] = ma35d1_clk_mux("ccap0_mux",
+ clk_base + REG_CLK_CLKSEL0,
+ 12, 1, ccap_sel_clks,
+ ARRAY_SIZE(ccap_sel_clks));
+ hws[CCAP0_DIV] = ma35d1_clk_divider("ccap0_div", "ccap0_mux",
+ clk_base + REG_CLK_CLKDIV1, 8, 4);
+ hws[CCAP0_GATE] = ma35d1_clk_gate("ccap0_gate", "ccap0_div",
+ clk_base + REG_CLK_SYSCLK0, 29);
+
+ /* CCAP1 */
+ hws[CCAP1_MUX] = ma35d1_clk_mux("ccap1_mux",
+ clk_base + REG_CLK_CLKSEL0,
+ 14, 1, ccap_sel_clks,
+ ARRAY_SIZE(ccap_sel_clks));
+ hws[CCAP1_DIV] = ma35d1_clk_divider("ccap1_div", "ccap1_mux",
+ clk_base + REG_CLK_CLKDIV1,
+ 12, 4);
+ hws[CCAP1_GATE] = ma35d1_clk_gate("ccap1_gate", "ccap1_div",
+ clk_base + REG_CLK_SYSCLK0, 30);
+
+ /* PDMA0~3 */
+ hws[PDMA0_GATE] = ma35d1_clk_gate("pdma0_gate", "hclk0",
+ clk_base + REG_CLK_SYSCLK1, 0);
+ hws[PDMA1_GATE] = ma35d1_clk_gate("pdma1_gate", "hclk0",
+ clk_base + REG_CLK_SYSCLK1, 1);
+ hws[PDMA2_GATE] = ma35d1_clk_gate("pdma2_gate", "hclk0",
+ clk_base + REG_CLK_SYSCLK1, 2);
+ hws[PDMA3_GATE] = ma35d1_clk_gate("pdma3_gate", "hclk0",
+ clk_base + REG_CLK_SYSCLK1, 3);
+
+ /* WH0~1 */
+ hws[WH0_GATE] = ma35d1_clk_gate("wh0_gate", "hclk0",
+ clk_base + REG_CLK_SYSCLK1, 4);
+ hws[WH1_GATE] = ma35d1_clk_gate("wh1_gate", "hclk0",
+ clk_base + REG_CLK_SYSCLK1, 5);
+
+ /* HWS */
+ hws[HWS_GATE] = ma35d1_clk_gate("hws_gate", "hclk0",
+ clk_base + REG_CLK_SYSCLK1, 6);
+
+ /* EBI */
+ hws[EBI_GATE] = ma35d1_clk_gate("ebi_gate", "hclk0",
+ clk_base + REG_CLK_SYSCLK1, 7);
+
+ /* SRAM0~1 */
+ hws[SRAM0_GATE] = ma35d1_clk_gate("sram0_gate", "hclk0",
+ clk_base + REG_CLK_SYSCLK1, 8);
+ hws[SRAM1_GATE] = ma35d1_clk_gate("sram1_gate", "hclk0",
+ clk_base + REG_CLK_SYSCLK1, 9);
+
+ /* ROM */
+ hws[ROM_GATE] = ma35d1_clk_gate("rom_gate", "hclk0",
+ clk_base + REG_CLK_SYSCLK1, 10);
+
+ /* TRA */
+ hws[TRA_GATE] = ma35d1_clk_gate("tra_gate", "hclk0",
+ clk_base + REG_CLK_SYSCLK1, 11);
+
+ /* DBG */
+ hws[DBG_MUX] = ma35d1_clk_mux("dbg_mux", clk_base + REG_CLK_CLKSEL0,
+ 27, 1, dbg_sel_clks,
+ ARRAY_SIZE(dbg_sel_clks));
+ hws[DBG_GATE] = ma35d1_clk_gate("dbg_gate", "hclk0",
+ clk_base + REG_CLK_SYSCLK1, 12);
+
+ /* CLKO */
+ hws[CKO_MUX] = ma35d1_clk_mux("cko_mux", clk_base + REG_CLK_CLKSEL4,
+ 24, 4, cko_sel_clks,
+ ARRAY_SIZE(cko_sel_clks));
+ hws[CKO_DIV] = ma35d1_clk_divider_pow2("cko_div", "cko_mux",
+ clk_base + REG_CLK_CLKOCTL,
+ 0, 4);
+ hws[CKO_GATE] = ma35d1_clk_gate("cko_gate", "cko_div",
+ clk_base + REG_CLK_SYSCLK1, 13);
+
+ /* GTMR */
+ hws[GTMR_GATE] = ma35d1_clk_gate("gtmr_gate", "hirc",
+ clk_base + REG_CLK_SYSCLK1, 14);
+
+ /* GPIO */
+ hws[GPA_GATE] = ma35d1_clk_gate("gpa_gate", "hclk0",
+ clk_base + REG_CLK_SYSCLK1, 16);
+ hws[GPB_GATE] = ma35d1_clk_gate("gpb_gate", "hclk0",
+ clk_base + REG_CLK_SYSCLK1, 17);
+ hws[GPC_GATE] = ma35d1_clk_gate("gpc_gate", "hclk0",
+ clk_base + REG_CLK_SYSCLK1, 18);
+ hws[GPD_GATE] = ma35d1_clk_gate("gpd_gate", "hclk0",
+ clk_base + REG_CLK_SYSCLK1, 19);
+ hws[GPE_GATE] = ma35d1_clk_gate("gpe_gate", "hclk0",
+ clk_base + REG_CLK_SYSCLK1, 20);
+ hws[GPF_GATE] = ma35d1_clk_gate("gpf_gate", "hclk0",
+ clk_base + REG_CLK_SYSCLK1, 21);
+ hws[GPG_GATE] = ma35d1_clk_gate("gpg_gate", "hclk0",
+ clk_base + REG_CLK_SYSCLK1, 22);
+ hws[GPH_GATE] = ma35d1_clk_gate("gph_gate", "hclk0",
+ clk_base + REG_CLK_SYSCLK1, 23);
+ hws[GPI_GATE] = ma35d1_clk_gate("gpi_gate", "hclk0",
+ clk_base + REG_CLK_SYSCLK1, 24);
+ hws[GPJ_GATE] = ma35d1_clk_gate("gpj_gate", "hclk0",
+ clk_base + REG_CLK_SYSCLK1, 25);
+ hws[GPK_GATE] = ma35d1_clk_gate("gpk_gate", "hclk0",
+ clk_base + REG_CLK_SYSCLK1, 26);
+ hws[GPL_GATE] = ma35d1_clk_gate("gpl_gate", "hclk0",
+ clk_base + REG_CLK_SYSCLK1, 27);
+ hws[GPM_GATE] = ma35d1_clk_gate("gpm_gate", "hclk0",
+ clk_base + REG_CLK_SYSCLK1, 28);
+ hws[GPN_GATE] = ma35d1_clk_gate("gpn_gate", "hclk0",
+ clk_base + REG_CLK_SYSCLK1, 29);
+
+ /* TIMER0~11 */
+ hws[TMR0_MUX] = ma35d1_clk_mux("tmr0_mux", clk_base + REG_CLK_CLKSEL1,
+ 0, 3, timer0_sel_clks,
+ ARRAY_SIZE(timer0_sel_clks));
+ hws[TMR0_GATE] = ma35d1_clk_gate("tmr0_gate", "tmr0_mux",
+ clk_base + REG_CLK_APBCLK0, 0);
+ hws[TMR1_MUX] = ma35d1_clk_mux("tmr1_mux", clk_base + REG_CLK_CLKSEL1,
+ 4, 3, timer1_sel_clks,
+ ARRAY_SIZE(timer1_sel_clks));
+ hws[TMR1_GATE] = ma35d1_clk_gate("tmr1_gate", "tmr1_mux",
+ clk_base + REG_CLK_APBCLK0, 1);
+ hws[TMR2_MUX] = ma35d1_clk_mux("tmr2_mux", clk_base + REG_CLK_CLKSEL1,
+ 8, 3, timer2_sel_clks,
+ ARRAY_SIZE(timer2_sel_clks));
+ hws[TMR2_GATE] = ma35d1_clk_gate("tmr2_gate", "tmr2_mux",
+ clk_base + REG_CLK_APBCLK0, 2);
+ hws[TMR3_MUX] = ma35d1_clk_mux("tmr3_mux", clk_base + REG_CLK_CLKSEL1,
+ 12, 3, timer3_sel_clks,
+ ARRAY_SIZE(timer3_sel_clks));
+ hws[TMR3_GATE] = ma35d1_clk_gate("tmr3_gate", "tmr3_mux",
+ clk_base + REG_CLK_APBCLK0, 3);
+ hws[TMR4_MUX] = ma35d1_clk_mux("tmr4_mux", clk_base + REG_CLK_CLKSEL1,
+ 16, 3, timer4_sel_clks,
+ ARRAY_SIZE(timer4_sel_clks));
+ hws[TMR4_GATE] = ma35d1_clk_gate("tmr4_gate", "tmr4_mux",
+ clk_base + REG_CLK_APBCLK0, 4);
+ hws[TMR5_MUX] = ma35d1_clk_mux("tmr5_mux", clk_base + REG_CLK_CLKSEL1,
+ 20, 3, timer5_sel_clks,
+ ARRAY_SIZE(timer5_sel_clks));
+ hws[TMR5_GATE] = ma35d1_clk_gate("tmr5_gate", "tmr5_mux",
+ clk_base + REG_CLK_APBCLK0, 5);
+ hws[TMR6_MUX] = ma35d1_clk_mux("tmr6_mux", clk_base + REG_CLK_CLKSEL1,
+ 24, 3, timer6_sel_clks,
+ ARRAY_SIZE(timer6_sel_clks));
+ hws[TMR6_GATE] = ma35d1_clk_gate("tmr6_gate", "tmr6_mux",
+ clk_base + REG_CLK_APBCLK0, 6);
+ hws[TMR7_MUX] = ma35d1_clk_mux("tmr7_mux", clk_base + REG_CLK_CLKSEL1,
+ 28, 3, timer7_sel_clks,
+ ARRAY_SIZE(timer7_sel_clks));
+ hws[TMR7_GATE] = ma35d1_clk_gate("tmr7_gate", "tmr7_mux",
+ clk_base + REG_CLK_APBCLK0, 7);
+ hws[TMR8_MUX] = ma35d1_clk_mux("tmr8_mux", clk_base + REG_CLK_CLKSEL2,
+ 0, 3, timer8_sel_clks,
+ ARRAY_SIZE(timer8_sel_clks));
+ hws[TMR8_GATE] = ma35d1_clk_gate("tmr8_gate", "tmr8_mux",
+ clk_base + REG_CLK_APBCLK0, 8);
+ hws[TMR9_MUX] = ma35d1_clk_mux("tmr9_mux", clk_base + REG_CLK_CLKSEL2,
+ 4, 3, timer9_sel_clks,
+ ARRAY_SIZE(timer9_sel_clks));
+ hws[TMR9_GATE] = ma35d1_clk_gate("tmr9_gate", "tmr9_mux",
+ clk_base + REG_CLK_APBCLK0, 9);
+ hws[TMR10_MUX] = ma35d1_clk_mux("tmr10_mux",
+ clk_base + REG_CLK_CLKSEL2,
+ 8, 3, timer10_sel_clks,
+ ARRAY_SIZE(timer10_sel_clks));
+ hws[TMR10_GATE] = ma35d1_clk_gate("tmr10_gate", "tmr10_mux",
+ clk_base + REG_CLK_APBCLK0, 10);
+ hws[TMR11_MUX] = ma35d1_clk_mux("tmr11_mux",
+ clk_base + REG_CLK_CLKSEL2,
+ 12, 3, timer11_sel_clks,
+ ARRAY_SIZE(timer11_sel_clks));
+ hws[TMR11_GATE] = ma35d1_clk_gate("tmr11_gate", "tmr11_mux",
+ clk_base + REG_CLK_APBCLK0, 11);
+
+ /* UART0~16 */
+ hws[UART0_MUX] = ma35d1_clk_mux("uart0_mux",
+ clk_base + REG_CLK_CLKSEL2,
+ 16, 2, uart_sel_clks,
+ ARRAY_SIZE(uart_sel_clks));
+ hws[UART0_DIV] = ma35d1_clk_divider("uart0_div", "uart0_mux",
+ clk_base + REG_CLK_CLKDIV1,
+ 16, 4);
+ hws[UART0_GATE] = ma35d1_clk_gate("uart0_gate", "uart0_div",
+ clk_base + REG_CLK_APBCLK0, 12);
+ hws[UART1_MUX] = ma35d1_clk_mux("uart1_mux",
+ clk_base + REG_CLK_CLKSEL2,
+ 18, 2, uart_sel_clks,
+ ARRAY_SIZE(uart_sel_clks));
+ hws[UART1_DIV] = ma35d1_clk_divider("uart1_div", "uart1_mux",
+ clk_base + REG_CLK_CLKDIV1,
+ 20, 4);
+ hws[UART1_GATE] = ma35d1_clk_gate("uart1_gate", "uart1_div",
+ clk_base + REG_CLK_APBCLK0, 13);
+ hws[UART2_MUX] = ma35d1_clk_mux("uart2_mux",
+ clk_base + REG_CLK_CLKSEL2,
+ 20, 2, uart_sel_clks,
+ ARRAY_SIZE(uart_sel_clks));
+ hws[UART2_DIV] = ma35d1_clk_divider("uart2_div", "uart2_mux",
+ clk_base + REG_CLK_CLKDIV1,
+ 24, 4);
+ hws[UART2_GATE] = ma35d1_clk_gate("uart2_gate", "uart2_div",
+ clk_base + REG_CLK_APBCLK0, 14);
+ hws[UART3_MUX] = ma35d1_clk_mux("uart3_mux",
+ clk_base + REG_CLK_CLKSEL2,
+ 22, 2, uart_sel_clks,
+ ARRAY_SIZE(uart_sel_clks));
+ hws[UART3_DIV] = ma35d1_clk_divider("uart3_div", "uart3_mux",
+ clk_base + REG_CLK_CLKDIV1,
+ 28, 4);
+ hws[UART3_GATE] = ma35d1_clk_gate("uart3_gate", "uart3_div",
+ clk_base + REG_CLK_APBCLK0, 15);
+ hws[UART4_MUX] = ma35d1_clk_mux("uart4_mux",
+ clk_base + REG_CLK_CLKSEL2,
+ 24, 2, uart_sel_clks,
+ ARRAY_SIZE(uart_sel_clks));
+ hws[UART4_DIV] = ma35d1_clk_divider("uart4_div", "uart4_mux",
+ clk_base + REG_CLK_CLKDIV2,
+ 0, 4);
+ hws[UART4_GATE] = ma35d1_clk_gate("uart4_gate", "uart4_div",
+ clk_base + REG_CLK_APBCLK0, 16);
+ hws[UART5_MUX] = ma35d1_clk_mux("uart5_mux",
+ clk_base + REG_CLK_CLKSEL2,
+ 26, 2, uart_sel_clks,
+ ARRAY_SIZE(uart_sel_clks));
+ hws[UART5_DIV] = ma35d1_clk_divider("uart5_div", "uart5_mux",
+ clk_base + REG_CLK_CLKDIV2,
+ 4, 4);
+ hws[UART5_GATE] = ma35d1_clk_gate("uart5_gate", "uart5_div",
+ clk_base + REG_CLK_APBCLK0, 17);
+ hws[UART6_MUX] = ma35d1_clk_mux("uart6_mux",
+ clk_base + REG_CLK_CLKSEL2,
+ 28, 2, uart_sel_clks,
+ ARRAY_SIZE(uart_sel_clks));
+ hws[UART6_DIV] = ma35d1_clk_divider("uart6_div", "uart6_mux",
+ clk_base + REG_CLK_CLKDIV2,
+ 8, 4);
+ hws[UART6_GATE] = ma35d1_clk_gate("uart6_gate", "uart6_div",
+ clk_base + REG_CLK_APBCLK0, 18);
+ hws[UART7_MUX] = ma35d1_clk_mux("uart7_mux",
+ clk_base + REG_CLK_CLKSEL2,
+ 30, 2, uart_sel_clks,
+ ARRAY_SIZE(uart_sel_clks));
+ hws[UART7_DIV] = ma35d1_clk_divider("uart7_div", "uart7_mux",
+ clk_base + REG_CLK_CLKDIV2,
+ 12, 4);
+ hws[UART7_GATE] = ma35d1_clk_gate("uart7_gate", "uart7_div",
+ clk_base + REG_CLK_APBCLK0, 19);
+ hws[UART8_MUX] = ma35d1_clk_mux("uart8_mux",
+ clk_base + REG_CLK_CLKSEL3,
+ 0, 2, uart_sel_clks,
+ ARRAY_SIZE(uart_sel_clks));
+ hws[UART8_DIV] = ma35d1_clk_divider("uart8_div", "uart8_mux",
+ clk_base + REG_CLK_CLKDIV2,
+ 16, 4);
+ hws[UART8_GATE] = ma35d1_clk_gate("uart8_gate", "uart8_div",
+ clk_base + REG_CLK_APBCLK0, 20);
+ hws[UART9_MUX] = ma35d1_clk_mux("uart9_mux",
+ clk_base + REG_CLK_CLKSEL3,
+ 2, 2, uart_sel_clks,
+ ARRAY_SIZE(uart_sel_clks));
+ hws[UART9_DIV] = ma35d1_clk_divider("uart9_div", "uart9_mux",
+ clk_base + REG_CLK_CLKDIV2,
+ 20, 4);
+ hws[UART9_GATE] = ma35d1_clk_gate("uart9_gate", "uart9_div",
+ clk_base + REG_CLK_APBCLK0, 21);
+ hws[UART10_MUX] = ma35d1_clk_mux("uart10_mux",
+ clk_base + REG_CLK_CLKSEL3,
+ 4, 2, uart_sel_clks,
+ ARRAY_SIZE(uart_sel_clks));
+ hws[UART10_DIV] = ma35d1_clk_divider("uart10_div", "uart10_mux",
+ clk_base + REG_CLK_CLKDIV2,
+ 24, 4);
+ hws[UART10_GATE] = ma35d1_clk_gate("uart10_gate", "uart10_div",
+ clk_base + REG_CLK_APBCLK0, 22);
+ hws[UART11_MUX] = ma35d1_clk_mux("uart11_mux",
+ clk_base + REG_CLK_CLKSEL3,
+ 6, 2, uart_sel_clks,
+ ARRAY_SIZE(uart_sel_clks));
+ hws[UART11_DIV] = ma35d1_clk_divider("uart11_div", "uart11_mux",
+ clk_base + REG_CLK_CLKDIV2,
+ 28, 4);
+ hws[UART11_GATE] = ma35d1_clk_gate("uart11_gate", "uart11_div",
+ clk_base + REG_CLK_APBCLK0, 23);
+ hws[UART12_MUX] = ma35d1_clk_mux("uart12_mux",
+ clk_base + REG_CLK_CLKSEL3,
+ 8, 2, uart_sel_clks,
+ ARRAY_SIZE(uart_sel_clks));
+ hws[UART12_DIV] = ma35d1_clk_divider("uart12_div", "uart12_mux",
+ clk_base + REG_CLK_CLKDIV3,
+ 0, 4);
+ hws[UART12_GATE] = ma35d1_clk_gate("uart12_gate", "uart12_div",
+ clk_base + REG_CLK_APBCLK0, 24);
+ hws[UART13_MUX] = ma35d1_clk_mux("uart13_mux",
+ clk_base + REG_CLK_CLKSEL3,
+ 10, 2, uart_sel_clks,
+ ARRAY_SIZE(uart_sel_clks));
+ hws[UART13_DIV] = ma35d1_clk_divider("uart13_div", "uart13_mux",
+ clk_base + REG_CLK_CLKDIV3,
+ 4, 4);
+ hws[UART13_GATE] = ma35d1_clk_gate("uart13_gate", "uart13_div",
+ clk_base + REG_CLK_APBCLK0, 25);
+ hws[UART14_MUX] = ma35d1_clk_mux("uart14_mux",
+ clk_base + REG_CLK_CLKSEL3,
+ 12, 2, uart_sel_clks,
+ ARRAY_SIZE(uart_sel_clks));
+ hws[UART14_DIV] = ma35d1_clk_divider("uart14_div", "uart14_mux",
+ clk_base + REG_CLK_CLKDIV3,
+ 8, 4);
+ hws[UART14_GATE] = ma35d1_clk_gate("uart14_gate", "uart14_div",
+ clk_base + REG_CLK_APBCLK0, 26);
+ hws[UART15_MUX] = ma35d1_clk_mux("uart15_mux",
+ clk_base + REG_CLK_CLKSEL3,
+ 14, 2, uart_sel_clks,
+ ARRAY_SIZE(uart_sel_clks));
+ hws[UART15_DIV] = ma35d1_clk_divider("uart15_div", "uart15_mux",
+ clk_base + REG_CLK_CLKDIV3,
+ 12, 4);
+ hws[UART15_GATE] = ma35d1_clk_gate("uart15_gate", "uart15_div",
+ clk_base + REG_CLK_APBCLK0, 27);
+ hws[UART16_MUX] = ma35d1_clk_mux("uart16_mux",
+ clk_base + REG_CLK_CLKSEL3,
+ 16, 2, uart_sel_clks,
+ ARRAY_SIZE(uart_sel_clks));
+ hws[UART16_DIV] = ma35d1_clk_divider("uart16_div", "uart16_mux",
+ clk_base + REG_CLK_CLKDIV3,
+ 16, 4);
+ hws[UART16_GATE] = ma35d1_clk_gate("uart16_gate", "uart16_div",
+ clk_base + REG_CLK_APBCLK0, 28);
+
+ /* RTC */
+ hws[RTC_GATE] = ma35d1_clk_gate("rtc_gate", "lxt",
+ clk_base + REG_CLK_APBCLK0, 29);
+
+ /* DDRP */
+ hws[DDR_GATE] = ma35d1_clk_gate("ddr_gate", "ddrpll",
+ clk_base + REG_CLK_APBCLK0, 30);
+
+ /* KPI */
+ hws[KPI_MUX] = ma35d1_clk_mux("kpi_mux", clk_base + REG_CLK_CLKSEL4,
+ 30, 1, kpi_sel_clks,
+ ARRAY_SIZE(kpi_sel_clks));
+ hws[KPI_DIV] = ma35d1_clk_divider("kpi_div", "kpi_mux",
+ clk_base + REG_CLK_CLKDIV4,
+ 24, 8);
+ hws[KPI_GATE] = ma35d1_clk_gate("kpi_gate", "kpi_div",
+ clk_base + REG_CLK_APBCLK0, 31);
+
+ /* I2C0~5 */
+ hws[I2C0_GATE] = ma35d1_clk_gate("i2c0_gate", "pclk0",
+ clk_base + REG_CLK_APBCLK1, 0);
+ hws[I2C1_GATE] = ma35d1_clk_gate("i2c1_gate", "pclk1",
+ clk_base + REG_CLK_APBCLK1, 1);
+ hws[I2C2_GATE] = ma35d1_clk_gate("i2c2_gate", "pclk2",
+ clk_base + REG_CLK_APBCLK1, 2);
+ hws[I2C3_GATE] = ma35d1_clk_gate("i2c3_gate", "pclk0",
+ clk_base + REG_CLK_APBCLK1, 3);
+ hws[I2C4_GATE] = ma35d1_clk_gate("i2c4_gate", "pclk1",
+ clk_base + REG_CLK_APBCLK1, 4);
+ hws[I2C5_GATE] = ma35d1_clk_gate("i2c5_gate", "pclk2",
+ clk_base + REG_CLK_APBCLK1, 5);
+
+ /* QSPI0~1 */
+ hws[QSPI0_MUX] = ma35d1_clk_mux("qspi0_mux",
+ clk_base + REG_CLK_CLKSEL4,
+ 8, 2, qspi0_sel_clks,
+ ARRAY_SIZE(qspi0_sel_clks));
+ hws[QSPI0_GATE] = ma35d1_clk_gate("qspi0_gate", "qspi0_mux",
+ clk_base + REG_CLK_APBCLK1, 6);
+ hws[QSPI1_MUX] = ma35d1_clk_mux("qspi1_mux",
+ clk_base + REG_CLK_CLKSEL4,
+ 10, 2, qspi1_sel_clks,
+ ARRAY_SIZE(qspi1_sel_clks));
+ hws[QSPI1_GATE] = ma35d1_clk_gate("qspi1_gate", "qspi1_mux",
+ clk_base + REG_CLK_APBCLK1, 7);
+
+ /* SMC0~1 */
+ hws[SMC0_MUX] = ma35d1_clk_mux("smc0_mux",
+ clk_base + REG_CLK_CLKSEL4,
+ 28, 1, smc_sel_clks,
+ ARRAY_SIZE(smc_sel_clks));
+ hws[SMC0_DIV] = ma35d1_clk_divider("smc0_div", "smc0_mux",
+ clk_base + REG_CLK_CLKDIV1,
+ 0, 4);
+ hws[SMC0_GATE] = ma35d1_clk_gate("smc0_gate", "smc0_div",
+ clk_base + REG_CLK_APBCLK1, 12);
+
+ hws[SMC1_MUX] = ma35d1_clk_mux("smc1_mux",
+ clk_base + REG_CLK_CLKSEL4,
+ 29, 1, smc_sel_clks,
+ ARRAY_SIZE(smc_sel_clks));
+ hws[SMC1_DIV] = ma35d1_clk_divider("smc1_div", "smc1_mux",
+ clk_base + REG_CLK_CLKDIV1,
+ 4, 4);
+ hws[SMC1_GATE] = ma35d1_clk_gate("smc1_gate", "smc1_div",
+ clk_base + REG_CLK_APBCLK1, 13);
+
+ /* WDT0~2 */
+ hws[WDT0_MUX] = ma35d1_clk_mux("wdt0_mux",
+ clk_base + REG_CLK_CLKSEL3,
+ 20, 2, wdt0_sel_clks,
+ ARRAY_SIZE(wdt0_sel_clks));
+ hws[WDT0_GATE] = ma35d1_clk_gate("wdt0_gate", "wdt0_mux",
+ clk_base + REG_CLK_APBCLK1, 16);
+ hws[WDT1_MUX] = ma35d1_clk_mux("wdt1_mux",
+ clk_base + REG_CLK_CLKSEL3,
+ 24, 2, wdt1_sel_clks,
+ ARRAY_SIZE(wdt1_sel_clks));
+ hws[WDT1_GATE] = ma35d1_clk_gate("wdt1_gate", "wdt1_mux",
+ clk_base + REG_CLK_APBCLK1, 17);
+ hws[WDT2_MUX] = ma35d1_clk_mux("wdt2_mux",
+ clk_base + REG_CLK_CLKSEL3,
+ 28, 2, wdt2_sel_clks,
+ ARRAY_SIZE(wdt2_sel_clks));
+ hws[WDT2_GATE] = ma35d1_clk_gate("wdt2_gate", "wdt2_mux",
+ clk_base + REG_CLK_APBCLK1, 18);
+
+ /* WWDT0~2 */
+ hws[WWDT0_MUX] = ma35d1_clk_mux("wwdt0_mux",
+ clk_base + REG_CLK_CLKSEL3,
+ 22, 2, wwdt0_sel_clks,
+ ARRAY_SIZE(wwdt0_sel_clks));
+ hws[WWDT1_MUX] = ma35d1_clk_mux("wwdt1_mux",
+ clk_base + REG_CLK_CLKSEL3,
+ 26, 2, wwdt1_sel_clks,
+ ARRAY_SIZE(wwdt1_sel_clks));
+ hws[WWDT2_MUX] = ma35d1_clk_mux("wwdt2_mux",
+ clk_base + REG_CLK_CLKSEL3,
+ 30, 2, wwdt2_sel_clks,
+ ARRAY_SIZE(wwdt2_sel_clks));
+
+ /* EPWM0~2 */
+ hws[EPWM0_GATE] = ma35d1_clk_gate("epwm0_gate", "pclk1",
+ clk_base + REG_CLK_APBCLK1, 24);
+ hws[EPWM1_GATE] = ma35d1_clk_gate("epwm1_gate", "pclk2",
+ clk_base + REG_CLK_APBCLK1, 25);
+ hws[EPWM2_GATE] = ma35d1_clk_gate("epwm2_gate", "pclk1",
+ clk_base + REG_CLK_APBCLK1, 26);
+
+ /* I2S0~1 */
+ hws[I2S0_MUX] = ma35d1_clk_mux("i2s0_mux",
+ clk_base + REG_CLK_CLKSEL4,
+ 12, 2, i2s0_sel_clks,
+ ARRAY_SIZE(i2s0_sel_clks));
+ hws[I2S0_GATE] = ma35d1_clk_gate("i2s0_gate", "i2s0_mux",
+ clk_base + REG_CLK_APBCLK2, 0);
+ hws[I2S1_MUX] = ma35d1_clk_mux("i2s1_mux",
+ clk_base + REG_CLK_CLKSEL4,
+ 14, 2, i2s1_sel_clks,
+ ARRAY_SIZE(i2s1_sel_clks));
+ hws[I2S1_GATE] = ma35d1_clk_gate("i2s1_gate", "i2s1_mux",
+ clk_base + REG_CLK_APBCLK2, 1);
+
+ /* SSMCC */
+ hws[SSMCC_GATE] = ma35d1_clk_gate("ssmcc_gate", "pclk3",
+ clk_base + REG_CLK_APBCLK2, 2);
+
+ /* SSPCC */
+ hws[SSPCC_GATE] = ma35d1_clk_gate("sspcc_gate", "pclk3",
+ clk_base + REG_CLK_APBCLK2, 3);
+
+ /* SPI0~3 */
+ hws[SPI0_MUX] = ma35d1_clk_mux("spi0_mux",
+ clk_base + REG_CLK_CLKSEL4,
+ 0, 2, spi0_sel_clks,
+ ARRAY_SIZE(spi0_sel_clks));
+ hws[SPI0_GATE] = ma35d1_clk_gate("spi0_gate", "spi0_mux",
+ clk_base + REG_CLK_APBCLK2, 4);
+ hws[SPI1_MUX] = ma35d1_clk_mux("spi1_mux",
+ clk_base + REG_CLK_CLKSEL4,
+ 2, 2, spi1_sel_clks,
+ ARRAY_SIZE(spi1_sel_clks));
+ hws[SPI1_GATE] = ma35d1_clk_gate("spi1_gate", "spi1_mux",
+ clk_base + REG_CLK_APBCLK2, 5);
+ hws[SPI2_MUX] = ma35d1_clk_mux("spi2_mux",
+ clk_base + REG_CLK_CLKSEL4,
+ 4, 2, spi2_sel_clks,
+ ARRAY_SIZE(spi2_sel_clks));
+ hws[SPI2_GATE] = ma35d1_clk_gate("spi2_gate", "spi2_mux",
+ clk_base + REG_CLK_APBCLK2, 6);
+ hws[SPI3_MUX] = ma35d1_clk_mux("spi3_mux",
+ clk_base + REG_CLK_CLKSEL4,
+ 6, 2, spi3_sel_clks,
+ ARRAY_SIZE(spi3_sel_clks));
+ hws[SPI3_GATE] = ma35d1_clk_gate("spi3_gate", "spi3_mux",
+ clk_base + REG_CLK_APBCLK2, 7);
+
+ /* ECAP0~2 */
+ hws[ECAP0_GATE] = ma35d1_clk_gate("ecap0_gate", "pclk1",
+ clk_base + REG_CLK_APBCLK2, 8);
+ hws[ECAP1_GATE] = ma35d1_clk_gate("ecap1_gate", "pclk2",
+ clk_base + REG_CLK_APBCLK2, 9);
+ hws[ECAP2_GATE] = ma35d1_clk_gate("ecap2_gate", "pclk1",
+ clk_base + REG_CLK_APBCLK2, 10);
+
+ /* QEI0~2 */
+ hws[QEI0_GATE] = ma35d1_clk_gate("qei0_gate", "pclk1",
+ clk_base + REG_CLK_APBCLK2, 12);
+ hws[QEI1_GATE] = ma35d1_clk_gate("qei1_gate", "pclk2",
+ clk_base + REG_CLK_APBCLK2, 13);
+ hws[QEI2_GATE] = ma35d1_clk_gate("qei2_gate", "pclk1",
+ clk_base + REG_CLK_APBCLK2, 14);
+
+ /* ADC */
+ hws[ADC_DIV] = ma35d1_reg_adc_clkdiv(dev, "adc_div", "pclk0", 0,
+ clk_base + REG_CLK_CLKDIV4,
+ 4, 17, 0x1ffff);
+ hws[ADC_GATE] = ma35d1_clk_gate("adc_gate", "adc_div",
+ clk_base + REG_CLK_APBCLK2, 24);
+
+ /* EADC */
+ hws[EADC_DIV] = ma35d1_clk_divider_table("eadc_div", "pclk2",
+ clk_base + REG_CLK_CLKDIV4,
+ 0, 4, eadc_div_table);
+ hws[EADC_GATE] = ma35d1_clk_gate("eadc_gate", "eadc_div",
+ clk_base + REG_CLK_APBCLK2, 25);
+
+ ret = of_clk_add_hw_provider(clk_node, of_clk_hw_onecell_get,
+ ma35d1_hw_data);
+ if (ret < 0) {
+ dev_err(dev, "failed to register hws for MA35D1\n");
+ iounmap(clk_base);
+ }
+ return ret;
+}
+
+static const struct of_device_id ma35d1_clk_of_match[] = {
+ { .compatible = "nuvoton,ma35d1-clk" },
+ { },
+};
+MODULE_DEVICE_TABLE(of, ma35d1_clk_of_match);
+
+static struct platform_driver ma35d1_clk_driver = {
+ .probe = ma35d1_clocks_probe,
+ .driver = {
+ .name = "ma35d1-clk",
+ .of_match_table = ma35d1_clk_of_match,
+ },
+};
+
+static int __init ma35d1_clocks_init(void)
+{
+ return platform_driver_register(&ma35d1_clk_driver);
+}
+
+postcore_initcall(ma35d1_clocks_init);
+
+MODULE_AUTHOR("Chi-Fang Li<cfli0@nuvoton.com>");
+MODULE_DESCRIPTION("NUVOTON MA35D1 Clock Driver");
+MODULE_LICENSE("GPL v2");
new file mode 100644
@@ -0,0 +1,198 @@
+/* SPDX-License-Identifier: GPL-2.0-only */
+/*
+ * Copyright (C) 2023 Nuvoton Technology Corp.
+ * Author: Chi-Fang Li <cfli0@nuvoton.com>
+ */
+
+#ifndef __DRV_CLK_NUVOTON_MA35D1_H
+#define __DRV_CLK_NUVOTON_MA35D1_H
+
+#include <linux/clk.h>
+#include <linux/clkdev.h>
+#include <linux/clk-provider.h>
+#include <linux/spinlock.h>
+#include <linux/regmap.h>
+#include <linux/mfd/syscon.h>
+#include <linux/mfd/ma35d1-sys.h>
+
+enum ma35d1_pll_type {
+ MA35D1_CAPLL,
+ MA35D1_DDRPLL,
+ MA35D1_APLL,
+ MA35D1_EPLL,
+ MA35D1_VPLL,
+};
+
+enum ma35d1_pll_mode {
+ VSIPLL_INTEGER_MODE,
+ VSIPLL_FRACTIONAL_MODE,
+ VSIPLL_SS_MODE,
+};
+
+/* VSI-PLL CTL0~2 */
+#define VSIPLL_CTL0 0x0
+#define VSIPLL_CTL1 0x4
+#define VSIPLL_CTL2 0x8
+
+/* VSI-PLL Specification limits */
+#define VSIPLL_FREF_MAX_FREQ 200000000UL
+#define VSIPLL_FREF_MIN_FREQ 1000000UL
+#define VSIPLL_FREFDIVM_MAX_FREQ 40000000UL
+#define VSIPLL_FREFDIVM_MIN_FREQ0 1000000UL
+#define VSIPLL_FREFDIVM_MIN_FREQ1 10000000UL
+#define VSIPLL_FCLK_MAX_FREQ 2400000000UL
+#define VSIPLL_FCLK_MIN_FREQ 600000000UL
+#define VSIPLL_FCLKO_MAX_FREQ 2400000000UL
+#define VSIPLL_FCLKO_MIN_FREQ 85700000UL
+#define VSIPLL_SPREAD_RANGE 194
+#define VSIPLL_MODULATION_FREQ 50000
+
+/* Clock Control Registers Offset */
+#define REG_CLK_PWRCTL (0x00)
+#define REG_CLK_SYSCLK0 (0x04)
+#define REG_CLK_SYSCLK1 (0x08)
+#define REG_CLK_APBCLK0 (0x0C)
+#define REG_CLK_APBCLK1 (0x10)
+#define REG_CLK_APBCLK2 (0x14)
+#define REG_CLK_CLKSEL0 (0x18)
+#define REG_CLK_CLKSEL1 (0x1C)
+#define REG_CLK_CLKSEL2 (0x20)
+#define REG_CLK_CLKSEL3 (0x24)
+#define REG_CLK_CLKSEL4 (0x28)
+#define REG_CLK_CLKDIV0 (0x2C)
+#define REG_CLK_CLKDIV1 (0x30)
+#define REG_CLK_CLKDIV2 (0x34)
+#define REG_CLK_CLKDIV3 (0x38)
+#define REG_CLK_CLKDIV4 (0x3C)
+#define REG_CLK_CLKOCTL (0x40)
+#define REG_CLK_STATUS (0x50)
+#define REG_CLK_PLL0CTL0 (0x60)
+#define REG_CLK_PLL2CTL0 (0x80)
+#define REG_CLK_PLL2CTL1 (0x84)
+#define REG_CLK_PLL2CTL2 (0x88)
+#define REG_CLK_PLL3CTL0 (0x90)
+#define REG_CLK_PLL3CTL1 (0x94)
+#define REG_CLK_PLL3CTL2 (0x98)
+#define REG_CLK_PLL4CTL0 (0xA0)
+#define REG_CLK_PLL4CTL1 (0xA4)
+#define REG_CLK_PLL4CTL2 (0xA8)
+#define REG_CLK_PLL5CTL0 (0xB0)
+#define REG_CLK_PLL5CTL1 (0xB4)
+#define REG_CLK_PLL5CTL2 (0xB8)
+#define REG_CLK_CLKDCTL (0xC0)
+#define REG_CLK_CLKDSTS (0xC4)
+#define REG_CLK_CDUPB (0xC8)
+#define REG_CLK_CDLOWB (0xCC)
+#define REG_CLK_CKFLTRCTL (0xD0)
+#define REG_CLK_TESTCLK (0xF0)
+#define REG_CLK_PLLCTL (0x40)
+
+/* Constant Definitions for Clock Controller */
+#define SMICPLLCTL0_FBDIV_POS (0)
+#define SMICPLLCTL0_FBDIV_MSK (0xfful << SMICPLLCTL0_FBDIV_POS)
+#define SMICPLLCTL0_INDIV_POS (8)
+#define SMICPLLCTL0_INDIV_MSK (0xful << SMICPLLCTL0_INDIV_POS)
+#define SMICPLLCTL0_OUTDIV_POS (12)
+#define SMICPLLCTL0_OUTDIV_MSK (0x3ul << SMICPLLCTL0_OUTDIV_POS)
+#define SMICPLLCTL0_PD_POS (16)
+#define SMICPLLCTL0_PD_MSK (0x1ul << SMICPLLCTL0_PD_POS)
+#define SMICPLLCTL0_BP_POS (17)
+#define SMICPLLCTL0_BP_MSK (0x1ul << SMICPLLCTL0_BP_POS)
+#define VSIPLLCTL0_FBDIV_POS (0)
+#define VSIPLLCTL0_FBDIV_MSK (0x7fful << VSIPLLCTL0_FBDIV_POS)
+#define VSIPLLCTL0_INDIV_POS (12)
+#define VSIPLLCTL0_INDIV_MSK (0x3ful << VSIPLLCTL0_INDIV_POS)
+#define VSIPLLCTL0_MODE_POS (18)
+#define VSIPLLCTL0_MODE_MSK (0x3ul << VSIPLLCTL0_MODE_POS)
+#define VSIPLLCTL0_SSRATE_POS (20)
+#define VSIPLLCTL0_SSRATE_MSK (0x7fful << VSIPLLCTL0_SSRATE_POS)
+#define VSIPLLCTL1_PD_POS (0)
+#define VSIPLLCTL1_PD_MSK (0x1ul << VSIPLLCTL1_PD_POS)
+#define VSIPLLCTL1_BP_POS (1)
+#define VSIPLLCTL1_BP_MSK (0x1ul << VSIPLLCTL1_BP_POS)
+#define VSIPLLCTL1_OUTDIV_POS (4)
+#define VSIPLLCTL1_OUTDIV_MSK (0x7ul << VSIPLLCTL1_OUTDIV_POS)
+#define VSIPLLCTL1_FRAC_POS (8)
+#define VSIPLLCTL1_FRAC_MSK (0xfffffful << VSIPLLCTL1_FRAC_POS)
+#define VSIPLLCTL2_SLOPE_POS (0)
+#define VSIPLLCTL2_SLOPE_MSK (0xfffffful << VSIPLLCTL2_SLOPE_POS)
+
+struct clk_hw *ma35d1_reg_clk_pll(enum ma35d1_pll_type type, u8 u8mode,
+ const char *name, const char *parent,
+ unsigned long targetFreq,
+ void __iomem *base,
+ struct regmap *regmap);
+
+struct clk_hw *ma35d1_reg_adc_clkdiv(struct device *dev,
+ const char *name,
+ const char *parent_name,
+ unsigned long flags,
+ void __iomem *reg, u8 shift,
+ u8 width, u32 mask_bit);
+
+extern spinlock_t ma35d1_lock;
+
+static inline struct clk_hw *ma35d1_clk_fixed(const char *name, int rate)
+{
+ return clk_hw_register_fixed_rate(NULL, name, NULL, 0, rate);
+}
+
+static inline struct clk_hw *ma35d1_clk_mux(const char *name,
+ void __iomem *reg, u8 shift,
+ u8 width,
+ const char *const *parents,
+ int num_parents)
+{
+ return clk_hw_register_mux(NULL, name, parents, num_parents,
+ CLK_SET_RATE_NO_REPARENT, reg, shift,
+ width, 0, &ma35d1_lock);
+}
+
+static inline struct clk_hw *ma35d1_clk_divider(const char *name,
+ const char *parent,
+ void __iomem *reg, u8 shift,
+ u8 width)
+{
+ return clk_hw_register_divider(NULL, name, parent, CLK_SET_RATE_PARENT,
+ reg, shift, width, 0, &ma35d1_lock);
+}
+
+static inline struct clk_hw *ma35d1_clk_divider_pow2(const char *name,
+ const char *parent,
+ void __iomem *reg,
+ u8 shift, u8 width)
+{
+ return clk_hw_register_divider(NULL, name, parent,
+ CLK_DIVIDER_POWER_OF_TWO, reg, shift,
+ width, 0, &ma35d1_lock);
+}
+
+static inline struct clk_hw *ma35d1_clk_divider_table(const char *name,
+ const char *parent,
+ void __iomem *reg,
+ u8 shift, u8 width,
+ const struct clk_div_table *table)
+{
+ return clk_hw_register_divider_table(NULL, name, parent, 0,
+ reg, shift, width, 0, table,
+ &ma35d1_lock);
+}
+
+static inline struct clk_hw *ma35d1_clk_fixed_factor(const char *name,
+ const char *parent,
+ unsigned int mult,
+ unsigned int div)
+{
+ return clk_hw_register_fixed_factor(NULL, name, parent,
+ CLK_SET_RATE_PARENT, mult, div);
+}
+
+static inline struct clk_hw *ma35d1_clk_gate(const char *name,
+ const char *parent,
+ void __iomem *reg, u8 shift)
+{
+ return clk_hw_register_gate(NULL, name, parent, CLK_SET_RATE_PARENT,
+ reg, shift, 0, &ma35d1_lock);
+}
+
+#endif /* __DRV_CLK_NUVOTON_MA35D1_H */